Time to read: 6 minutes 25 seconds | Updated: February 28, 2025

Wi-Fi 7

What is Wi-Fi 7

Wi-Fi 7 (IEEE 802.11be) is the new standard from the Wi-Fi Alliance that provides significant performance improvements over previous Wi-Fi generations. Like Wi-Fi 6E, Wi-Fi 7 uses the 6 GHz band to greatly increase Wi-Fi capacity by providing access to up to 1200 MHz of additional spectrum. Wi-Fi 7 introduces important capabilities that include ultra-wide 320 MHz channels for more data at faster speeds, Multi-link operations (MLO) for greater reliability, and 4K QAM for higher peak data rates.

W-Fi 7 is ideal for use cases that demand high bandwidth, low latency, and extremely reliable W-Fi connectivity. Backward compatibility with support for 2.4 GHz, 5 GHz bands in addition to the 6 GHz band, helps ensure that previous generations of devices will be able to connect.

Explore the HPE Aruba Networking Access Points

Wi-Fi 7 connected smart goggles.

What are the key features of Wi-Fi 7?
What are the benefits of Wi-Fi 7?
Considerations for choosing Wi-Fi 7 access points
What are the HPE Aruba Networking Wi-Fi 7 solutions?

What are the key features of Wi-Fi 7?

What are the key features of Wi-Fi 7?

Wi-Fi 7, also known as IEEE 802.11be, extends the capabilities of Wi-Fi 6E with significant new capabilities:

Ultra-wide 320 MHz bandwidth channels double the transmission capacity of the 160 MHz channels supported by Wi-Fi 6. This increase in bandwidth helps to reduce delays and improve overall transmission rates.
Multi-Link Operation (MLO) for channel aggregation that enables devices connected to a Wi-Fi 7 access point to combine different channels across frequency bands, allowing concurrent transmission and reception of data over multiple links. Prior to Wi-Fi 7, devices typically used a single band to transmit data.
4K QAM (Quadrature Amplitude Modulation) provides higher peak data rates by enabling each signal to more densely embed greater amounts of data. Data transmission efficiency and performance is significantly improved compared to the only 1K QAM with Wi-Fi 6 and Wi-Fi 6E
Spectrum puncturing helps accommodate interference in wide channels by allowing subchannels to operate within wide channels by opening up 20 MHz increments. This helps work around interference or other requirements while still enabling 320 MHz channels to function.

Tremendous wireless advancements have been made over the past 25 years, delivering benefits of performance, efficiencies, and security capabilities. As wireless standards evolve, W-Fi 7 also takes advantage of the efficiency features from W-Fi 6 and Wi-Fi 6E (IEEE 802.11ax) which include:

Orthogonal Frequency Division Multiple Access (OFDMA) is arguably the most important feature in the 802.11ax standard. This is an enhanced multi-user feature that effectively shares channels to increase network efficiency. Multiple devices with varying bandwidth needs can be served simultaneously instead of the existing model where devices compete with one another to send data. With 802.11ax there is no contention as each device is simultaneously scheduled to transmit data in parallel.

Handling data packets in this way improves performance, as a large number of packets — especially those that are latency sensitive such as voice traffic — can be transmitted simultaneously. In dense environments, instead of using a single vehicle to carry traffic, it’s like using a carpool model. Traffic is pooled into a transport allowing for multiple conversations to happen at once. This allows access points to handle traffic from multiple 802.11ax devices more efficiently and at peak performance.

Multi-user Multiple Input/Multiple Output (MU-MIMO) is an additional way to handle traffic from multiple devices that was originally introduced in 802.11ac. Within 802.11ax, this feature has been enhanced by allowing multiple devices to transmit simultaneously. This allows for large packets such as streaming HD video to be handled more efficiently, while shorter packets from IoT devices and voice traffic would be better handled using OFDMA.
Target Wake Time (TWT) minimizes device contention and extends the battery life of clients, which lets devices remain inactive until it’s their turn to transmit data using a scheduling scheme negotiated with the APs. Because devices can go into an inactive mode the battery life of smart phones, tablets and IoT devices is an underlying benefit. It’s like parking a vehicle in the cell phone waiting area, rather than circling the airport for arrivals. There is less congestion, energy savings and an overall better experience.
IoT handling is enhanced with an operating mode for low-power, low-bandwidth devices like sensors, automation and medical devices. This mode will separate these devices from an 802.11ax AP using a 20 MHz-only channel that works in either the 2.4 or 5 GHz bands. Like adding a dedicated bike lane, but without the worry of low-bandwidth traffic interfering with latency sensitive traffic.
Built-in Wi-Fi 6 encryption with Enhanced Open support helps keep guest traffic encrypted per user session and device. Guests can continue to connect to an “open” network but now enjoy a safer Wi-Fi experience without the added burden of doing anything extra. What’s more, WPA3 was introduced to replace WPA2 and enhance security for employee connections using more advanced algorithms and simpler configuration. Both solutions are easy for IT and users, while enhancing the posture of your networks.

What are the benefits of Wi-Fi 7?

What are the benefits of Wi-Fi 7?

Today’s W-Fi networks are limited by the available spectrum. As organizations increase their use of high-definition video streaming, onboard increasing numbers of client and IoT devices, and continue transitioning to cloud services, W-Fi congestion increases, and user experience suffers.

The W-Fi 6E standard opened the 6 GHz band, resulting in tremendous wireless capacity gains of up to 1200 MHz of additional spectrum and increasing W-Fi capacity by up to 3x. The new W-Fi 7 standard (IEEE 802.11be) builds on the capacity gains of this clean spectrum and introduces improvements to support increased density, provide extremely reliable low latency connectivity, and deliver the highest performance W-Fi available, for:

More data and many more simultaneous transmissions at faster speeds with 320 MHz channels that are double the width of Wi-Fi 6’s 160 MHz channels.
Improved load balancing and higher throughput with multilink operation (MLO) that enables W-Fi 7 devices to connect on different channels across frequency bands at the same time. Or both bands can be used concurrently to share redundant data for improved reliability with ultralow and precise latencies.
Higher peak data rates with 4K QAM that more densely packs data into each signal with higher transmission rates than W-Fi 6 for faster, low latency W-Fi.
Improved usage of wide channels by accommodating interference with spectrum puncturing.

Considerations for choosing Wi-Fi 7 access points

Considerations for choosing Wi-Fi 7 access points

When planning upgrades and refreshes of wireless infrastructure, organizations should consider future requirements for capacity, performance, and connectivity. Wi Fi 7 is engineered to offer reliable wireless experiences, making it suitable for emerging use cases that require high bandwidth, low latency, and dependable Wi Fi connectivity. Criteria for evaluating Wi-Fi 7 access points should include:

Simplify operations by using AI and machine learning to automate optimization and provide actionable recommendations to remediate issues.
Deliver built-in security with unified policy enforcement across wired and wireless networks and support for Policy Enforcement Firewall (PEF) capabilities.
Offer secure, energy efficient IoT capabilities to enable you to leverage access points as an IoT connectivity platform using Bluetooth Low Energy (BLE), Zigbee, or USB ports.
Enable self-location for indoor location services.
Provide flexibility to manage on-premise, in the cloud, or as a service and to deploy with or without gateways.
Be Wi-Fi CERTIFIED™ to indicate that they have met industry-agreed standards for interoperability, security, and a range of application specific protocols.

What are the HPE Aruba Networking Wi-Fi 7 solutions?

What are the HPE Aruba Networking Wi-Fi 7 solutions?

Critical user and IoT applications and AI workloads depend on secure, seamless connectivity. HPE Aruba Networking AI-powered Wi-Fi 7 delivers the high-performance, high-capacity coverage needed – managed by HPE Aruba Networking Central– for unified management, observability, and security across distributed wired and wireless environments.

HPE Aruba Networking’s Wi-Fi 7 solution includes the HPE Aruba Networking 750 Series Campus Access Points that optimize coverage and performance with customizable tri-band radio configuration for 2.4 GHz, 5 GHz, and 6 GHz bands by using the 2.4 GHz for dual 5 GHz or dual 6 GHz support (available in future software release). Powerful IoT support includes dual IoT radios (BLE and Zigbee) and two USB connectors. Dual 10 GbE wired ports, one with MACsec support (available in future software release), provide secure, high-speed, and redundant wired connectivity. Precision locationing with sub one meter accuracy supports a wide range of applications with floor level mapping. Patented ultra tri-band (UTB) filtering enables full use of the high end of 5 GHz with the lower end of 6 GHz without interference or limiting channels.

These game changing access points go beyond the standard to strengthen network security, provide precise location-based services, and create an IoT platform with enterprise-grade security, enabling enterprises to fully realize the value of their wireless investment and unlock operational efficiencies.

What is the difference between Wi-Fi 7 and Wi-Fi 6E?

Wi-Fi 6E and Wi-Fi 7 both take advantage of the 6 GHz band. However, Wi-Fi 7 is based on the IEEE 802.11be standard while Wi-Fi 6E is based on IEEE 802.11ax. Backward compatibility ensures that devices from previous generations will still be able to connect.

Wi-Fi 7 also features:

320 MHz bandwidth channels
Multi-link operation (MLO) for channel aggregation and failover
4K QAM for higher peak data rates

Spectrum puncturing to better accommodate interference in wide channels

	Wi-Fi 6E	Wi-Fi 7
Corresponding IEEE standard	802.11ax	802.11be
Use of 6GHz band	Yes	Yes
Key features	Up to 1200 MHz additional unlicensed spectrum* Up to seven 160MHz channels1 Up to 1024 QAM data rates WPA3 required	All the features of Wi-Fi 6E plus: Maximum 320MHz channels Multi-link operation (MLO) for aggregating channels Spectrum puncturing to minimize channel interference
What you should know	Not all countries have adopted 6GHz Europe has opened 500MHz vs 1200 in most other countries Standard Power, which is required for outdoor use, is pending approvals	Not all countries have adopted 6GHz Europe has opened 500MHz vs 1200 in most other countries Standard Power, which is required for outdoor use, is pending approvals Use of 4096 QAM data rates require a high signal-to-noise (SNR) and require very close proximity to an AP (several feet) AP coverage models simply do not allow for enough available channels to support 320MHz

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HPE Aruba Networking Central

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1Dependent on local regulations